Ripping and scraping cutter tool assemblies, systems, and methods for a tunnel boring machine
Embodiments of the invention generally relate to tunnel boring machine cutter assemblies, such as ripping and scraping cutter or tool assemblies, (collectively “cutter assemblies”), and related methods of use and manufacturing. The various embodiments of the cutter assemblies described herein may be used in tunnel boring machines (“TBMs”), earth pressure balance machines (“EPBs”), raise drilling systems, large diameter blind drilling systems, and other types of mechanical drilling and excavation systems.
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This application is a continuation of U.S. application Ser. No. 14/445,774 filed on Jul. 29, 2014, the disclosure of which is incorporated herein, in its entirety, by this reference.
BACKGROUNDVarious mechanical excavations systems may be used in a variety of excavating applications. For example, tunnel boring machines (“TBMs”) are commonly used in tunnel excavation. TBMs can bore through any number of materials, from hard rock to sand and can produce tunnels of different diameters. A typical TBM includes a rotating cutterhead that chips, cracks, scrapes, rips, and otherwise removes material during rotation. More specifically, TBMs may include ripping and scraping tools that may engage material as the cutterhead rotates. Furthermore, as the cutterhead removes material, the TBM may advance the cutterhead to facilitate further engagement of the cutterhead with material Likewise, the TBM may press the cutterhead against material to provide engagement of the cutterhead with the material.
After the material fails due to engagement with the cutterhead as the cutterhead rotates, the failed material is collected and removed as debris. As the ripping and scraping tools engage and fail the material, however, the tools commonly experience wear and/or breakage, which leads to failure or reduced effectiveness of the tools. Moreover, failure or reduced effectiveness of the tools may necessitate removal and replacement thereof. As such, the useful life of the tools may be a significant limitation in the operating efficiency of mechanical excavation systems using these tools, such as the TBMs.
For example, while the tools may be replaced, the mechanical excavation systems may require stoppage to change out the tools. Moreover, such stoppage may last several hours, as technicians remove, replace, and/or repair the tools. This time- and effort-intensive repair activity reduces the overall efficiency or rate of mechanical excavation systems using the disc cutters.
Therefore, manufacturers and users of mechanical excavation systems continue to seek improved ripping and scraping tools as well as manufacturing techniques therefor.
SUMMARYEmbodiments of the invention generally relate to tunnel boring machine cutter assemblies, such as ripping and scraping cutter or tool assemblies (collectively “cutter assemblies”), and related methods of use and manufacturing. The various embodiments of the cutter assemblies described herein may be used in TBMs, earth pressure balance machines (“EPBs”), raise drilling systems, large diameter blind drilling systems, and other types of mechanical drilling and excavation systems. In some embodiments, the cutter assemblies may include multiple superhard cutter elements that may engage, disrupt, and fail target material. As used herein' the term “target material” refers to material targeted for failing and/or removal. In particular, such superhard cutter elements may exhibit a relatively high wear resistance, which may increase the useful life of the cutter assemblies (as compared with conventional cutter assemblies, such as conventional rippers and scrapers).
Embodiments include a cutter assembly for mounting on a cutterhead of a TBM and engaging a target material. The cutter assembly includes a support block sized and configured to be attached to the cutterhead of the TBM and a plurality of superhard cutter elements (e.g., a plurality of PCD cutter elements). Each superhard cutter element includes a superhard working surface. Moreover, the superhard cutter elements are secured to the support block and oriented in a manner to engage the target material during movement (e.g., rotation) of the cutterhead of the TBM.
Embodiments also include a cutterhead for a TBM. The cutterhead includes a front surface oriented approximately perpendicular to a rotation axis, and a plurality of cutter assemblies protruding outward from the front surface. Each cutter assembly includes a support block, and a plurality of superhard cutter elements secured to the support block.
Embodiments also include a TBM for engaging, failing, and excavating target material. The TBM includes a rear portion configured to be secured relative to the target material and a cutterhead rotatably connected to the rear portion. The cutterhead has a front surface. Furthermore, the cutterhead is moveable into the target material. The TBM also includes a plurality of cutter assemblies secured to the cutterhead and positioned and oriented on the cutterhead in a manner to engage target material during rotation of the cutterhead. Each cutter assembly of the plurality of cutter assemblies includes a support block and a plurality of superhard cutter elements (e.g., a plurality of PCD cutter elements) secured to the support block.
Features from any of the disclosed embodiments may be used in combination with one another, without limitation. In addition, other features and advantages of the present disclosure will become apparent to those of ordinary skill in the art through consideration of the following detailed description and the accompanying drawings.
The drawings illustrate several embodiments, wherein identical reference numerals refer to identical or similar elements or features in different views or embodiments shown in the drawings.
Embodiments of the invention generally relate to tunnel boring machine cutter assemblies, such as ripping and scraping cutter or tool assemblies, (collectively “cutter assemblies”), and related methods of use and manufacturing. The various embodiments of the cutter assemblies described herein may be used in TBMs, earth pressure balance machines (“EPBs”), raise drilling systems, large diameter blind drilling systems, and other types of mechanical drilling and excavation systems. In some embodiments, the cutter assemblies may include multiple superhard cutter elements that may engage, disrupt, and fail target material. In particular, such superhard cutter elements may exhibit a relatively high wear resistance, which may increase the useful life of the cutter assemblies (as compared with conventional cutter assemblies, such as conventional rippers and scrapers).
In some embodiments, the cutter assembly is secured to a cutterhead of the TBM machine. Hence, as the cutterhead rotates about an axis of rotation, the cutter assembly also may rotate about the axis of rotation and engage the target material. The cutterhead may have a clockwise rotational direction and/or counterclockwise direction of rotation (i.e., TBM may rotate the cutterhead in either clockwise or counterclockwise direction). Similarly, the cutting direction or direction of movement of cutter assembly may vary from one embodiment to another. Embodiments may include working surfaces of the superhard cutter elements approximately oriented along the direction of rotation of the cutterhead (or direction of movement of the cutter assembly). For example, a working surface of the superhard cutter element may engage the target material during use or operation. In some embodiments, rotation of the cutterhead may produce such engagement of the superhard cutter elements with the target material in a manner that fails the target material.
The superhard cutter elements as well as the working surfaces and cutting edges thereof may have any number of suitable configurations that may vary from one embodiment to the next. In some embodiments, at least some of the superhard cutter elements may have approximately cylindrical shapes. Alternatively or additionally, the superhard cutter elements may have rectangular or square, triangular, polygonal, or irregular-shaped cross-sectional geometries. In any case, the superhard cutter elements may be secured to and/or within a support block that may be attached to the cutterhead of the TBM. In an embodiment, the working surfaces and/or the cutting edges of the superhard cutter elements may be positioned beyond a front surface of the cutterhead. For example, as the cutterhead advances toward and/or into the target material, the working surface and/or cutting edges may engage the target material, while the front surface of the cutter head may remain spaced away from the target material.
The working surface of the superhard cutter elements may have any number of suitable shapes, which may vary from one embodiment to the next. In some examples, the working surfaces may have a domed or a generally pointed shape, such as a hemispherical, a semispherical, an approximately conical shape with a rounded apex, or the like. Alternatively, the working surfaces may be planar or approximately planar, multi-faceted, or irregularly shaped. Furthermore, in one or more embodiments, the working surfaces may include superhard material. As used herein, “superhard material” includes materials exhibiting a hardness that is at least equal to the hardness of tungsten carbide (i.e., a portion or the entire working surface may have a hardness that exceeds the hardness of tungsten carbide). In any of the embodiments disclosed herein, the cutter assemblies and the superhard cutter elements may include one or more superhard materials, such as polycrystalline diamond, polycrystalline cubic boron nitride, silicon carbide, tungsten carbide, or any combination of the foregoing superhard materials. For example, a superhard cutter element may include a substrate and a superhard material bonded to the substrate, as described in further detail below.
As mentioned above, the cutter assemblies may be mounted or attached to the cutterhead of the TBM.
In some embodiments, the rotation axis 10 may be generally coaxial with the geometry of the excavation (e.g., concentric with a circular cross-section of a tunnel). The size of the TBM 100 (e.g., the size of the cutterhead 110) may vary from one embodiment to another. In some embodiments, the TBM 100 may have an approximately one meter diameter; in other embodiments, the TBM 100 may have an approximately 20 meter diameter. It should be appreciated that the TBM 100 may be about 1 meter in diameter to about 20 meters in diameter. In other embodiments, the TBM 100 may be less than 1 meter in diameter or greater than 20 meters in diameter.
In an embodiment, one or more cutter assemblies 120 may be at least one of mounted on, attached to, or integrated with the cutterhead 110. Generally, the cutter assemblies 120 may protrude outward from a front surface 111 of the cutterhead 110 (i.e., in the cutting direction) and may be attached to the cutterhead 110 in any number of suitable ways, which may vary from one embodiment to the next. For example, at least some of the cutter assemblies 120 may be secured to the cutterhead 110 with one or more fasteners in a manner that facilitates service, removal, and replacement of such cutter assemblies 120. Alternatively or additionally, a clamping mechanism may secure the cutter assembly 120 to the cutterhead 110. In some embodiments, the cutter assemblies 120 may be welded to the cutterhead 110. In any event, in some embodiments, the cutter assemblies 120 may be removably secured to the cutterhead 110.
In an embodiment, the cutter assemblies 120 may be mounted to the cutterhead 110 in one or more patterns, such that as the cutterhead 110 rotates about the rotation axis 10, the cutter assemblies 120 can contact or engage the target material. Hence, the cutter assemblies 120 may be configured to for cutting, scraping, or otherwise failing the target material (e.g., rock, sand, gravel, etc.). For example, as the cutterhead 110 rotates and advances, the cutter assemblies 120 also rotate about the rotation axis 10 and are pressed or forced against the target material, thereby engaging and failing the target material. For example, a system of hydraulic cylinders (not shown) may advance the cutterhead 110 toward and into the target material.
As the cutter assemblies 120 engage the target material, movement of the cutter assembly 120 through the target material may fracture, crush, break, rip, scrape, or otherwise fail and loosen the excavated material from the bulk of the target material. In some embodiments, the excavated material may enter one or more removal channels, such as removal channels 130, which may pass through the front surface 111 of the cutterhead 110. It should be noted that the front surface 111 of the cutterhead 110 may have any number of suitable configurations. In some embodiments, the front surface 111 of the cutterhead 110 may be substantially planar. Alternatively, the front surface 111 of the cutterhead 110 may have a convex shape, a concave shape, undulations, as well as other suitable shapes. Moreover, in some embodiments, the front surface 111 of the cutterhead 110 may be oriented at approximately 90° angle relative to the rotation axis 10. Alternatively, however, the front surface may have a substantially non-orthogonal orientation relative to the rotation axis 10.
As illustrated in
Subsequently, the excavated material may be transported away from the cutterhead 110 and out of the TBM 100. As the target material is excavated and removed, the tunnel length increases, and the TBM 100 may advance farther into the tunnel, maintaining engagement of the cutterhead 110 with the target material. In some embodiments, a portion of the TBM 100 may be anchored or otherwise secured to and/or within the tunnel opening, while pressing the cutterhead 110 against the target material. For example, hydraulic cylinders may be deployed along with mechanisms that may press against the surface of the tunnel opening, thereby maintaining a portion (e.g., a rear portion 101) of the TBM 100 stationary as the cutterhead 110 is pressed against the target material. In an embodiment, the cutterhead 110 may be rotatably and movably coupled or connected to the rear portion 101. Hence, as the rear portion 101 remains fixed or stationary relative to the tunnel or ground, the cutterhead 110 may be rotated and advanced into the target material.
As described above, the cutter assembly 120 may include superhard cutter elements sized and configured to engage and fail the target material as the cutterhead 110 rotates and advances therein. Configuration of the cutter assembly 120 may vary from one embodiment to the next and may depend on the specifics of the material target for excavation, among other things. In an embodiment illustrated in
The superhard cutter elements 150a, 150a′ may be secured to the support block 140a in any number of suitable ways. For example, the superhard cutter elements 150a, 150a′ may be at least partially secured within respective recesses in the support block 140a by brazing, press-fitting, threadedly attaching, fastening with a fastener, combinations of the foregoing, or another suitable technique. In any event, the superhard cutter elements 150a, 150a′ may be removably or non-removably secured to the support block 140a in a manner that maintains the superhard cutter elements 150a, 150a′ attached to the support block 140a during operation of the cutter assembly 120a.
The support block 140a may have any shape and size suitable for securing the superhard cutter elements 150a, 150a′ in a manner that facilitates engagement thereof with the target material. In the embodiment illustrated in
Additionally, the support block 140a may include a single slanted surface or multiple slanted surfaces, which may facilitate cutting or ripping of the target material by the superhard cutter elements 150a, 150a′ and/or by the support block 140a. For example, the support block 140a may include longitudinally slanting surfaces, such as a longitudinal slanted surface 142a that may form a non-parallel and non-orthogonal angle relative to the mounting surface 141a. Specifically, the slanted surface 142a may extend at least partially along a length (as measured along longitudinal axis 35a) of the support block 140a and may form or define an upper portion of the support block 140a.
In some embodiments, the support block 140a also may have a second longitudinal slanted surface 143a, which may be a mirrored orientation/geometry of the slanted surface 142a (e.g., about a centerline of the support block 140a, such as vertical centerline 30a extending through the geometric center of the support block 140a). In other words, the slanted surfaces 142a, 143a may be symmetrical about the vertical centerline 30a of the support block 140a. Furthermore, in some embodiments, the slanted surfaces 142a and 143a may form a crest or edge 146a of the support block 140a (e.g., the edge 146a may form or define an upper edge of the support block 140a).
It should be appreciated that, unless otherwise expressly stated, all references to a “centerline” (e.g., references to a centerline of a cutter assembly, support block, superhard cutter elements, etc.) are used for descriptive purposes only. As such, references to a “centerline” are intended to provide orientation and/or positional references for describing elements and/or components of the cutter assembly. In some embodiments, the referenced “centerline” may coincide with a true center or line a line of symmetry of the cutter assembly or another referenced element or component thereof. In alternative embodiments, however, the referenced “centerline” does not necessarily coincide with a true center or line of symmetry of the cutter assembly or referenced element or component thereof. Furthermore, in some embodiments, when a cutter assembly is mounted on the cutterhead, the vertical centerline 30a of the cutter assembly may be substantially perpendicular to the front surface of the cutterhead (e.g., the front surface of the cutterhead may be substantially planar and/or may lie in an imaginary plane, and when the cutter assembly 120a is attached to the cutterhead, the vertical centerline 30a of the cutter assembly 120a may be substantially perpendicular to the imaginary plane of the front surface of the cutterhead).
As the support block 140a moves through the target material, the slanted surfaces 142a, 143a may provide relief, such that a smaller surface area of the support block 140a contacts the target material (as compared with support block shaped as a rectangular prismoid). For example, any of the slanted surfaces 142a, 143a may lie below superhard working surfaces of one or more superhard cutter elements 150a′, 150a′, such that the superhard cutter elements may at least partially fail and/or remove the target material, thereby reducing or minimizing contact between the target material and the slanted surfaces 142a, 143a. Reduced contacting surface area of the support block 140a with the target material may reduce friction of the support block 140a with the target material and may reduce wear of the support block 140a as well as reduce the amount of energy expended on rotation of the cutterhead.
Similarly, the support block 140a may include side-slanted surfaces, such as side-slanted surfaces 144a, 145a, which may form a non-parallel and/or non-orthogonal angle with the mounting surface 141a. Furthermore, the side-slanted surfaces 144a, 145a may form a non-parallel and non-orthogonal angle relative to the mounting surface 141a and relative to the slanted surface 142a of the support block 140a. The side-slanted surfaces 144a, 145a also may extend away from an imaginary plane defined by the vertical centerline 30a and longitudinal centerline 35a. In an embodiment, the side-slanted surfaces 144a, 145a may form non-parallel angles with the imaginary plane defined by the vertical centerline 30a and longitudinal centerline 35a.
In an embodiment, the mounting surface 141a may be approximately parallel to the imaginary plane defined by the vertical centerline 30a and longitudinal centerline 35a. Thus, for example, the side-slanted surfaces 144a, 145a may have a non-parallel orientation relative to the mounting surface 141a. Furthermore, the side-slanted surfaces 144a, 145a may form a ridge or an edge 147a therebetween, from which the side-slanted surfaces 144a, 145a may extend (e.g., the edge 147a may lie along the imaginary plane defined by the vertical centerline 30a and longitudinal centerline 35a).
The side-slanted surface 145a may have a mirrored orientation/geometry with respect to the 144a about the edge 147a. Also, in some embodiments, the edge 147a may be aligned with the longitudinal centerline 35a. Under some operating conditions, the edges 147a and 146a may aid in scraping the failed material into the openings in the cutterhead. As described above, after the failed material enters the openings in the cutterhead, the failed material may be transported away from the TBM.
In some embodiments, the support block 140a also may include side-slanted surfaces 148a, 149a, which may form edges or ridges with the side-slanted surfaces 144a, 145a, respectively (e.g., the side-slanted surfaces 148a and 144a may form an edge 153a). In an embodiment, the side-slanted surfaces 148a, 149a may form an edge or a ridge 154a therebetween. For example, the side-slanted surface 148a may have a mirrored orientation/geometry with respect to the side-slanted surface 149a about the ridge 154a. Alternatively, a surface may be formed between the side-slanted surfaces 148a, 149a.
Moreover, the side-slanted surfaces 148a, 149a may lie in an imaginary plane that is approximately parallel to the vertical centerline 30a of the support block 140a. In some embodiments, the edge 154a may lie in the same imaginary plane as the edge 147a (e.g., the edge 154a and the ridge 147a may lie in the imaginary plane defined by the vertical and longitudinal centerlines 30a, 35a). Similarly, the edge 147a may be aligned with or may lie in the same imaginary plane as the edge 146a (e.g., edges 146a, 147a may lie in the imaginary plane defined by the vertical and longitudinal centerlines 30a, 35a). In some embodiments, at least some of the superhard cutter elements 150a, 150a′ may extend from one or more surfaces extending between the slanted surfaces 142a, 143a, between the side-slanted surfaces 144a, 145a, between the side-slanted surfaces 148a, 149a, or combinations thereof.
Depending on the particular orientation on the cutterhead, in some embodiments, the cutter assembly 120a may move along the longitudinal centerline 35a and/or along a crosswise centerline 40a that is substantially perpendicular to the longitudinal centerline 35a. Accordingly, in some embodiments, the superhard cutter elements 150a, 150a′ may be oriented such that the superhard working surfaces 151a, 151a′ generally face in any selected direction (e.g., in the direction of rotation of the cutterhead of the TBM), such as to produce a desired or suitable cutting or ripping action when engaging the target material. In other words, as the cutter assembly 120a moves with the rotating cutterhead, the superhard working surfaces 151a, 151a′ may move through the target material in a manner that cuts, rips, or otherwise fails the target material and produces excavated material. It should be appreciated that references to the cutting direction are intended for descriptive purposes only and provide only some examples of suitable directions of movement of the cutter assemblies during operation thereof. Thus, such references are not intended to be limiting.
In some embodiments, an axis of the superhard cutter elements 150a, 150a′ (e.g., a center axis) may be oriented at a non-parallel angle relative to the longitudinal centerline 35a and/or relative to the crosswise centerline 40a of the cutter assembly 120a. For example, at least some of the cutter elements 150a and/or 150a′ may be oriented such that the axes thereof may form acute angles relative to an imaginary plane formed by the longitudinal centerline 35a and crosswise centerline 40a. As noted above, the superhard working surface may include any number of suitable shapes. In at least one example, the superhard working surfaces 151a may have cone shapes that may have any number suitable angles. For example, the cone of each of the superhard working surfaces 151a may be a 90° angle or other suitable angle. Moreover, in an embodiment, the cone of the superhard working surfaces 151a may include a concave surface 152a (e.g., a hemispherical or a semispherical portion a tip of the cone) that may blend with the peak of the conical surface of the superhard cutter elements 150a.
In some embodiments, the cutter assembly 120a may include multiple superhard cutter elements 150a, which may be arranged in any number of suitable configurations. In an embodiment, the superhard cutter elements 150a may be positioned in multiple rows along the length of the support block 140a (e.g., the rows may be substantially parallel to the longitudinal centerline 35a when viewed along vertical centerline 30a). More specifically, each row may include one or more of the superhard cutter elements 150a and may be spaced from each adjacent row. For example, the cutter assembly 120a may include an uppermost row of the superhard cutter elements 150a, which may be located at and/or may follow approximately the longitudinal centerline of the support block 140a when viewed along vertical centerline 30a.
As described above, in an embodiment, at least some of the superhard cutter elements 150a, 150a′ may be secured within recesses in the support block 140a. In some embodiments, such recesses may at least partially orient the superhard cutter elements 150a and/or 150a′ relative to the support block 140a. For example, center axes of at least some of the superhard cutter elements 150a may have a non-parallel orientation relative to the vertical centerline 30a of the support block 140a. More specifically, in some embodiments, the center axes of at least some of the superhard cutter elements 150a may form an acute angle with an imaginary plane formed by the vertical centerline 30a and crosswise centerline 40a.
In addition, in an embodiment, the center axis of each of the superhard cutter elements 150a may form the same angle with the imaginary plane formed by the vertical centerline 30a and crosswise centerline 40a. Alternatively, center axes of some or all of the superhard cutter elements 150a may form angles with the imaginary plane formed by the vertical centerline 30a and crosswise centerline 40a that are different from one another. In any event, the superhard cutter elements 150a may be oriented in a manner that movement of the cutter assembly 120a, while engaged with the target material, may produce ripping, scraping, or otherwise failing the target material by the superhard cutter elements 150a.
In an embodiment, the superhard cutter elements 150a may be located on the support block 140a such that as the cutter assembly 120a enters the target material, the superhard cutter elements 150a engage the target material. In some embodiments, the superhard cutter elements 150a may engage the target material at various depths and/or along multiple cutting paths. As such, the superhard cutter elements 150a may cut or rip through different layers or portions of the target material, which may be at different depths from one another (e.g., as measured along the direction of advancement of the TBM). Hence, such operation of the cutter assembly 120a may reduce load on any one of superhard cutter elements 150a, thereby increasing the useful life thereof.
In an embodiment, at least some of the superhard cutter elements may have a different configuration than other superhard cutter elements. For example, the superhard cutter element 151a′ may be different from the superhard cutter elements 151a. In some embodiments, the superhard cutter element 150a′ may have an at least partially convex (e.g., domed) superhard working surface 151a′. In an embodiment, the superhard working surface 151a′ may include flat or conical portions blended with a generally domed portion thereof. Accordingly, the superhard working surface 151a′ may have multiple superhard working surfaces that may engage the target material as the superhard cutter element 150a′ moves therethrough.
In some embodiments, the superhard cutter element 150a′ may be positioned at an uppermost portion or location of the support block 140a. Particularly, in an embodiment, the superhard cutter element 150a′ may be positioned in a manner that the superhard cutter element 150a′ is first to engage the target material, as the cutterhead of the TBM advances toward or into the target material. Therefore, the superhard cutter element 150a′ may provide initial engagement with or cutting or ripping of the target material.
In an embodiment, the superhard cutter element 150a′ may be positioned approximately at the longitudinal center of the support block 140a along the longitudinal axis 35a. Also, the superhard cutter element 150a′ may be positioned approximately at a crosswise center of the support block 140a. In other words, the superhard cutter element 150a′ may be positioned approximately in the center (from a top view) of the support block 140a. The superhard cutter element 150a′ also may be positioned in alignment with a row of the superhard cutter elements 150a (e.g., a row of superhard cutter elements mounted or affixed to the support block 140a along surface 143a of the support block 140a).
In some embodiments, the cutter assembly 120a may be symmetrical about one or more axes. For example, the above description of the cutter assembly 120a identifies surfaces 144a, 145a, 148a, 149a, illustrated on a left end portion 155a of the cutter assembly 120a. In an embodiment, the cutter assembly 120a may include similar or identically configured surfaces and/or superhard cutter elements 150a on a symmetrical right end portion 156a thereof.
In another embodiment, wear pads or elements may be affixed to a support block in combination with superhard cutter elements. For example, as illustrated in
The wear elements 160b may be positioned along any surface of the support block 140b. Furthermore, the wear elements 160b may include one or more cutting edges, which may engage the target material. In particular, the cutting edges of the wear elements 160b may scrape or otherwise fail and remove the target material and/or protect the support block 140a. The cutter assembly 120b also may include superhard cutter elements 150b (e.g., superhard cutter elements 150b′, 150b″, 150b″′), with the working surface of each of may be oriented at a non-parallel angle relative to a centerline 30b of the support block 140b. In some embodiments, the centerline 30b may be oriented approximately parallel to axis 10 of the TBM 100 (
In some embodiments, the superhard cutter elements 150b may include superhard working surfaces 151b. More specifically, as described below in further detail, the superhard working surfaces 151b may engage the target material during use. Furthermore, the superhard working surfaces may form one or more cutting edges, which may facilitate entry of the superhard cutter elements 150b into the target material.
In an embodiment, one, some, or all of the working surfaces of the superhard cutter elements 150b may face approximately in a first cutting direction (e.g., in a cutting direction 20b′). Additionally or alternatively, a first group of the working surfaces of the superhard cutter elements 150b may face generally toward the first cutting direction 20b′, while a second group of the working surfaces of the superhard cutter elements 150b may face generally toward second cutting direction 20b″. In an embodiment, as the cutterhead rotates in the first direction (e.g., in a clockwise direction), the cutter assembly 120b may move in the first cutting direction 20b′, and the first group of the superhard cutter elements 150b and/or wear elements 160b may engage and cut, rip, scrape, or otherwise fail the target material. Conversely, rotating the cutterhead in the second, opposite direction (e.g., in a counterclockwise direction), may move the cutter assembly 120b in the second cutting direction 20b″, thereby engaging the second group of the superhard cutter elements 150b and/or wear elements 160b with target material.
In some embodiments, the wear elements 160b may have a plate-like shape and may be secured within channels or recesses in that support block 140b. For example, the wear elements 160b may have a shape of an approximately triangular plate. Furthermore, in some embodiments, the wear elements 160b may have one or more truncated peaks (e.g., the peak at the uppermost portion of the wear elements 160b may be flat or approximately planar). In other words, an otherwise sharp peak of a triangular-shaped plate may be truncated to form planar portions of the wear elements 160b. In an embodiment, opposing cutting sides (e.g., cutting sides 161b′, 162b′ of the wear elements 160b′) may form or define the cutting edges of the wear elements 160b and may form an acute angle therebetween. Alternatively, the opposing cutting sides may form an obtuse angle therebetween.
The wear elements 160b may be brazed, fastened, press-fitted, or otherwise secured within the recesses in the support block 140b. In some embodiments, the wear elements 160b may be removably secured to and/or within that support block 140b, which may allow removal and/or replacement thereof. In any event, the wear elements 160b may be sufficiently secured within the recesses in the support block 140b to remain attached to the support block during operation of the cutter assembly 120b.
Furthermore, each of wear elements 160b may have a progressively decreasing size with increasing distance from the centerline 30b toward end portions 155b, 156b. For example, wear element 160b′may be the smallest of the wear elements 160b, while the wear elements 160b″′ may be the largest of the wear elements 160b. Also, cutting edges of the wear elements 160b may engage the target material at various depths, thereby reducing the load on a single wear element 160b that may operate at a greater depth of cut. In other words, as the cutter assembly 120b enters the target material, the wear element 160b′ may rip or scrape the target material at a first depth, thereby reducing the amount of material engaged by wear element 160b″. Similarly, the wear elements 160b′ and 160b″ may remove target material at first and second depths, respectively, thereby reducing the amount of target material engaged by the wear element 160b″′.
The wear elements 160b may include any suitable material, which may vary from one embodiment to the next. For example, the wear elements 160b may include cemented tungsten carbide, high speed steel, tool steel (e.g., A2, D2, etc.), case hardened steel, and the like. For example, steel wear elements may have hardness in one or more of the following ranges: between about 32 HRC and 45 HRC; between about 40 HRC and 55 HRC; between about 50 HRC and 60 HRC; or between about 58 HRC and 64 HRC. In some embodiments, hardness of steel cutter elements may be greater than 64 HRC or less than 32 HRC. Also, the wear elements 160b may be coated, and the coating may reduce friction of the wear elements 160b relative to the target material and/or may improve wear resistant characteristics of the wear elements 160b. For example, steel wear elements may be hardfaced with a tungsten carbide material.
As mentioned above, the cutter assembly 120b may include superhard cutter elements 150b. In some embodiments, at least one of the superhard cutter elements 150b may be secured to at least one of the wear elements 160b. For example, the superhard cutter elements 150b′ may be secured to and/or within the wear element 160b′. In particular, the superhard cutter elements 150b′ may be secured near or at an apex or the flat uppermost portion of the wear element 160b′. In an embodiment, the superhard cutter elements 150b′ may protrude above the uppermost portion of the wear element 160b′. For example, the superhard cutter elements 150b′ may include a polycrystalline diamond compact (described below in further detail), while the wear element 160b′ may include tungsten carbide (e.g., cobalt-cemented tungsten carbide). Consequently, the superhard cutter elements 150b′ may be sized and configured to protect the apex or an otherwise uppermost portion of the wear element 160b′ from wear, damage, breakage, or combinations thereof. That is, the superhard cutter elements 150b′ may engage the target material before the wear element 160b′ engages the target material, and may clear at least some target material from the path of the wear elements 160b.
Additionally or alternatively, the cutter assembly 120b may include one or more superhard cutter elements 150b positioned to precede one or more of the wear elements 160b during cutting (e.g., with respect to a cutting direction, such as one or more of the cutting directions 20b′, 20b″). For example, the superhard cutter element 150b″ may be positioned to precede at least one of the wear elements 160b″. In some embodiments, the superhard cutter element 150b″ may be attached to the support block 140b. In any event, as the cutter assembly 120b moves (e.g., in the cutting direction 20b′), the superhard cutter elements 150b″ may engage the target material before engagement thereof with the wear element 160b″. Consequently, the superhard cutter element 150b″ may cut, rip, or otherwise fail and remove at least a portion of the target material from the path of the wear element 160b″, which may increase the useful life of the wear elements 160b and/or of the cutter assembly 120b.
As mentioned above, the superhard cutter elements 150b may include superhard working surfaces 151b. Such superhard working surfaces 151b may have any suitable shape, size, and configuration, which may vary from one embodiment to the next. In the embodiment illustrated in
Furthermore, in an embodiment, the superhard working surfaces 151b may have a chamfer or a radius about a periphery thereof. The chamfer or radius may reduce or eliminate chipping or cracking of the superhard working surfaces 151b, during the operation of the cutter assembly 120b. Alternatively, the periphery of the working surfaces may be defined by a sharp edge.
As shown in
For example, the cutter assembly 120c may include a support block 140c that may secure the superhard cutter elements 150c as well as one or more wear elements 160c (not all labeled in
In one or more embodiments, the uppermost portion of each of the superhard cutter elements 150c may be located at approximately the same height (as measured from any surface (e.g., an imaginary surface) that is perpendicular to the centerline 30c). Accordingly, some or all of the superhard cutter elements 150c may engage the target material substantially simultaneously with one another, depending on the rate at which a TBM is moving forward, the rate of rotation of such TBM, and the relation of the support block 140c with respect to the TBM. Furthermore, similar to the cutter assembly 120b (
It should be appreciated that at least some cutter assemblies may be configured to cut, rip, scrape, or otherwise fail the target material when engaging the target material with two or more regions, end portions, surfaces of a support block, or combinations thereof. Particularly, such cutter assemblies may fail and/or remove the target material as the cutterhead rotates. At least one embodiment includes a cutter assembly configured to cut, rip, scrape, or otherwise fail the target material when target material engages one end portion, region or surface of the support block. For example,
In an embodiment, the support block 140d may have an approximately cuboid shape. For example, one or more sides of the support block 140d may facilitate mounting or securing the cutter assembly 120d to the cutterhead. Also, in some embodiments, a leading side 155d of the support block 140d (e.g., the side generally facing in direction 20d) may include one or more features configured to provide relief during engagement of the superhard cutter elements 150d with the target material. For example, the leading side 155d of the support block 140d may include a substantially vertical portion 141d, which may be substantially parallel to a centerline 30d of the cutter assembly 120d. The leading side also may include an angled portion 142d, which together with the vertical portion 141d may provide cutting relief for the superhard cutter elements 150d. More specifically, the angled portion 142d and the vertical portion 141d may form an obtuse angle 143d therebetween. For example, the obtuse angle 143d may be greater than 90 degrees, about 100 degrees to about 160 degrees, about 110 degrees to about 140 degrees, or other suitable obtuse angle. In any event, as the superhard working surfaces 151d engage and excavate the target material, the excavated material may enter or fall toward and move along the angled portion 142d toward the vertical portion 141d.
In some embodiments, the superhard cutter elements 150d may be oriented at an acute angle relative to the centerline 30b. Furthermore, as mentioned above, the superhard cutter elements 150d may include a substantially planar working surfaces 151d. Consequently, in an embodiment, the superhard working surfaces 151d may have an acute back rake angle 144d (as measured relative to an imaginary line parallel with the centerline 30d of the cutter assembly 120d), such that as the upper portions of the superhard working surfaces 151d engage the target material and fails and/or excavates the target material, the excavated material may move along the superhard working surfaces 151d and away from the uppermost portions thereof. In some embodiments, the upper portions of the superhard working surfaces 151d may experience the higher load (as compared with other portions of the 151d). The back rake angle 144d, however, may reduce the load experienced by the uppermost portions of the superhard working surfaces 151d by channeling the excavated material away therefrom, which may reduce or eliminate clogging or buildup of the excavated material on the uppermost portions of the superhard working surfaces 151d.
In an embodiment, the cutter assembly 120d may optionally include one or more wear elements 160d protruding outward from a top surface 145d of the support block 140d. The wear elements 160d may facilitate failing the target material and/or scraping the failed material toward one or more openings in the surface of the cutterhead. For example, as the cutter assembly 120d moves in direction 20d, working surfaces 161d of the wear elements 160d may engage the target material and/or the failed material to urge the target and/or failed material toward an opening in the cutterhead. The wear elements 160d may also protect top surface 145d of the support block 140d from excessive wear from contact with the target material.
In some embodiments, each of the wear elements 160d may include a substantially planar working surface 161d. Also, optionally, the working surfaces 161d of the wear elements 160d may be oriented in a direction substantially parallel relative to the centerline 30d of the cutter assembly 120d. Optionally, the working surfaces 161d may be substantially parallel to the top surface 145d of the support block 140d. Moreover, as mentioned above, in some embodiments, when the cutter assembly 120d is mounted to the cutterhead, the centerline 30d may be oriented approximately parallel to axis 10 of TBM (
As described above, the superhard cutter elements 150d of the cutter assembly 120d may exhibit the back rake angle 144d, which may facilitate failing the target material as the cutter assembly 120d engages the target material. The back rake angle 144d may vary from one embodiment to the next. For example, in the embodiment illustrated in
Additionally or alternatively, a cutter assembly may include superhard cutter elements that have slanted superhard working surfaces oriented at a non-perpendicular angle relative to the center axes of the respective superhard cutter elements, which may produce a suitable back rake angle. For example,
In some embodiments, the superhard working surfaces 151e may have a back rake angle 144e that may be in one or more of the same ranges as the back rake angle 144d (
In any case, the failed material may move along the superhard working surface 151e and onto the leading surface 141e. As new or additional failed material moves across the leading surface 141e, material previously present at or near the leading surface 141e may be pushed away (e.g., into an opening in the front surface of the cutterhead) by the new material. Accordingly, the cutter assembly 120e may fail the target material and channel the failed and into one or more openings in the front surface of the cutterhead.
In some embodiments, a cutter assembly also may include superhard cutter elements that have non-cylindrical geometries. For example,
In an embodiment, the top portions 155f may be approximately parallel with a top surface 141f of the support block 140f, which, in turn, may be approximately perpendicular to a centerline 30f. Alternatively, the top portions 155f may form an obtuse angle with the top surface 141f, thereby providing a relief for the failed material between the cutting edges 152f and the top surface 141f. In any event, in at least one embodiment, the top portions 155f may protrude above the top surface 141f of the support block 140f.
In some embodiments, the side bevels 153f, 154f may be relieved relative to the cutting edges 152f formed thereby. In other words, as the cutter assembly 120f moves and engages the target material and the cutting edges 152f engage the target material, the side bevels 153f and the 154f are oriented in a manner to reduce or minimize contact with the target material and to reduce drag forces experienced by the cutter assembly 120f. Additionally, the superhard cutter elements 150f may include a back bevel 156f, which may provide further relief and space for the failed material.
As mentioned above, in some embodiments, the superhard cutter elements of the cutter assembly may have an acute back rake angle, which may facilitate failing and/or removing or excavating target material. Alternatively, however, at least some of the superhard cutter elements of the cutter assembly may have no back rake angle. For example, the superhard working surfaces 151f of the superhard cutter elements 150f may be oriented substantially parallel to the centerline 30f. Furthermore, as the cutter assembly 120f fails the target material, the excavated material formed thereby may move along a leading side 142f of the support block 140f and toward or into one or more openings in the front surface of the cutterhead.
As described above, the superhard cutter elements may have any number of suitable configurations.
The superhard cutter elements 150g may include domed superhard working surfaces 151g, which may engage the target material. For example, the domed superhard working surfaces 151g may operate without chipping or cracking when impacting or engaging hard target material (e.g., rocks). In some embodiments, the domed superhard working surfaces 151g may cause the target material to crack, fracture, or otherwise fail. Moreover, the cutterhead may include cutter assemblies and/or superhard cutter elements that may engage the target material after the superhard cutter elements 150g. For example, additional cutter assemblies (which may be mounted on the cutterhead of the TBM) as well as superhard cutter elements may scrape or otherwise remove the failed material, producing the excavated material that may be removed by the TBM (
As described above, in addition to the superhard cutter elements that face generally in a selected direction, a cutter assembly may include superhard cutter elements positioned at any selected orientation. Moreover, in some embodiments, a cutter assembly may include one or more superhard cutter elements on a leading surface thereof.
For example, the cutter assembly 120h may include superhard cutter elements 150h (not all labeled in
In an embodiment, the wear element 160h′ may be positioned on and/or in a top surface 141h of the support block 140h. Furthermore, the top surface of the wear element 160h′ may be substantially planar and, in some embodiments, may be approximately parallel to the top surface 141h of the support block 140h. In some embodiments, the top surface 141h may form a non-perpendicular angle with a back surface 142h of the support block 140h, which may be approximately parallel with a centerline 30h. For example, the top surface 141h and the back surface 142h may form an obtuse angle therebetween.
Moreover, in some embodiments, the back surface 142h and a leading side 143h may have a non-parallel orientation relative to each other. For example, the leading side 143h and the back surface 142h may form an acute angle. In other words, the leading side 143h may form an acute angle with the centerline 30h. In additional or alternative embodiments, the leading side 143 also may form an acute angle with the top surface 141h. As such, the excavated material may have clearance to be pushed along the leading side 143h and/or along the top surface 141h.
Particularly, in an embodiment, the wear element 160h′ may have a continuous working surface that may extend along the top surface 141h a distance less than, equal to, or exceeding the distance spanned by the superhard cutter elements 150h. For example, the working surface of the wear element 160h′ may extend across the support block 140h to approximately the same lateral extent at least four of the superhard cutter elements 150h. As such, the target material ripped or at least partially failed by the superhard cutter elements 150h may be scraped and removed or excavated by scraping action of the wear element 160h′. In other words, the superhard cutter elements 150h may rip, disrupt, or otherwise loosen the target material, while the wear element 160h′ may remove or excavate the loosened material.
The cutter assembly 120h also may optionally include wear elements 160h″ (not all labeled in
In some embodiments, the wear elements 160h″ may be substantially cylindrical (e.g., the wear elements 160h″ may be similar to or the same as the wear elements 160d (
The wear element 160h′ and/or wear elements 160h″ may be secured in corresponding recesses in the support block 140h. In some embodiments, the recesses may form continuous through-channels to which the wear element 160h′ and/or wear elements 160h″ may be secured (e.g., by brazing, press-fitting, mechanical fastening, etc.). Specifically, the wear element 160h′ and/or the wear elements 160h″ may be secured in the same or similar manner as the wear elements 160b (
In some embodiments, the wear elements 160h′ and 160″ may have sharp corners, including edges 162h′, 162h″, which may be at least partially formed by working surfaces 161h′, 161h″ respectively. This disclosure, however, is not so limited. In an embodiment, the cutting edges 162h′, 162h″ may include a chamfer or a radius that may span a portion or the entire periphery of the respective working surface of the 161h′, 161h″.
As mentioned above, any of the superhard cutter elements described herein and combinations thereof may be included in any of the cutter assemblies.
In one or more embodiments, the cutter assembly 120k may include one or more superhard wear elements positioned on a back surface 141k (i.e., opposite to the leading side) thereof. For example, the cutter assembly 120k may include superhard wear elements 160k′ (not all labeled in
In an embodiment, a longitudinal axis of the superhard wear elements 160k′ may be oriented approximately perpendicular to a centerline 30k of the cutter assembly 120k. Additionally, the superhard wear elements 160k′ may be arranged in any number of suitable configurations, which may vary from one embodiment to the next. In at least one embodiment, the superhard wear elements 160k′ may be arranged in multiple rows and aligned columns (e.g., two rows and three columns, as shown in
As described above, the cutterhead of the TBM may move in a clockwise or counterclockwise direction, thereby moving the cutter assembly 120k in a first direction 20k′ or in a second direction 20k″. As such, when the cutter assembly 120k moves in the first direction 20k′, the superhard cutter elements 150k may engage, cut, rip, or otherwise fail the target material. Optionally, the cutter assembly 120k may engage, cut, rip, or otherwise fail the target material in both the first and second directions 20k′, 20k″. Furthermore, the superhard wear elements 160k′ may shield or protect the back surface 141k of the support block 140k during operation of the cutter assembly 120.
As described above, in some embodiments, the leading surface 141m and the top surface 142m may form an acute angle therebetween. Moreover, in an embodiment, a center axis of the superhard wear elements 160m may be aligned approximately perpendicular to the top surface 142m. In any event, the superhard wear elements 160m may protect the top surface 142m during operation of the cutter assembly, which may increase useful life of the cutter assembly 120m.
The shape and size of the support block as well as positions, orientations, shapes, and sizes of the superhard cutter elements may vary from one embodiment to the next.
In an embodiment, at least some of the superhard cutter elements 150n may be located on the center portion 141n and some may be located on the base portion 142n. For example, superhard cutter elements 150n′ (not all labeled in
Moreover, it should be appreciated that spacing and arrangement of the superhard cutter elements 150n′ and/or superhard cutter elements 150n″ may vary from one embodiment to the next. In an embodiment, one, some, or all of the center axes of the superhard cutter elements 150n′ and/or superhard cutter elements 150n″ may be substantially parallel with one or more surfaces of the support block 140n. For example, at least one of the center axes of the superhard cutter elements 150n′ may be substantially parallel with the shelf surface 144n. Similarly, for example, at least one of the center axes of the superhard cutter elements 150n″ may be substantially parallel the vertical surface 143n.
In an embodiment, the superhard cutter elements 150n′ and/or superhard cutter elements 150n″ may have domed (e.g., semispherical or other convex geometry) superhard working surfaces. As noted above, however, this disclosure is not so limited. In particular, the superhard cutter elements 150n′ and/or superhard cutter elements 150n″ may have any suitable shape and may be, for example, cone-shaped, pyramid-shaped, and the like. In any event, as the superhard cutter elements 150n′ and/or superhard cutter elements 150n″ engage the target material, the superhard cutter elements 150n′, 150n″ may pinch, compress, rip, or otherwise fail the target material. Also, as the cutter assembly 120n fails the target material, the failed material may slide along the domed superhard working surfaces of the superhard cutter elements 150n′, 150n″. Such sliding of the failed material may reduce binding thereof to the superhard cutter elements 150n, thereby providing an improved, direct contact of the superhard cutter elements 150n′ and/or 150n″ with the target material.
As noted above, the cutter assembly 120n may optionally include superhard cutter elements 150p. More specifically, in some embodiments, the superhard cutter elements 150p may be positioned on a top surface 145n of the support block 140n. For example, the top surface 145n may be substantially planar and the superhard cutter elements 150p may be oriented approximately perpendicular to the top surface 145n. Consequently, as the cutter assembly 120n moves through the target material, the superhard cutter elements 150p may engage, cut, rip, or otherwise fail the target material. Moreover, the superhard cutter elements 150p may protect the top surface 145n from abrasion and wear during operation.
In some embodiments, the superhard cutter elements 150p may be smaller than the superhard cutter elements 150n. Thus, in an embodiment, the superhard cutter elements 150p may be more densely arranged next to one another than the superhard cutter elements 150n. In other words, the superhard cutter elements 150p may be configured in any desired manner to provide coverage for the top surface 145n (e.g., similar to or different from the configuration of the shelf surface 144n provided by the superhard cutter elements 150n″). Also, as described above, any of the cutter assemblies described herein may include continuous or elongated superhard wear elements that may span along a surface of the support block, which may be cemented tungsten carbide, such as cobalt-cemented tungsten carbide. Some or at least one of such superhard cutter elements may be or may include polycrystalline diamond compacts. In an embodiment, at least one of the superhard cutter elements may include a tungsten carbide cutter element. For example,
In an embodiment, the support block 140r may be a substantially cubic prismoid or cuboid. For example, the superhard cutter elements 150r may be positioned on a top surface 141r of the support block 140r and may be oriented approximately perpendicular thereto. Generally, however, it should be appreciated that arrangement, orientation, positions, and number of the superhard cutter elements may vary from one embodiment to another. Moreover, shapes and sizes of the superhard cutter elements 150r also may vary from one embodiment the next. In an embodiment, the superhard cutter elements 150r may have an approximately pointed or conical shape (e.g., similar to the shape of the superhard cutter elements 150a (
As noted above, the cutter assembly 120r also may optionally include superhard wear elements 150r′. For example, the superhard wear elements 150r′ may be positioned on a front surface 142r of the support block 140r. In some embodiments, when the support block 140r is mounted on the cutterhead of the TBM (
In some embodiments, the superhard wear elements 150r′ may be domed (e.g., semispherical or other convex geometry). Also, the superhard wear elements 150r′ may be smaller than the superhard cutter elements 150r, such as exhibit a smaller maximum diameter or other lateral dimension. In any event, however, the superhard wear elements 150r′ may fail the target material and/or may at least partially protect the front surface 142r of the support block 140r, thereby extending useful life of the cutter assembly 120r.
In some embodiments, the cutter assembly 120r may include wear elements 160r secured to a side surface 143r. As noted above, the cutter assembly 120r may have an approximately cuboid shape. Thus, in an embodiment, the wear elements 160r may be oriented approximately perpendicular relative to the superhard wear elements 150r′.
As the cutter assembly 120r enters the target material, the wear elements 160r also may engage and cut, scrape, or otherwise fail the target material. For example, the wear elements 160r′, 160r″ may include multiple corresponding cutting edges 161r′, 161r″. In an embodiment, the cutting edges 161r′, 161r″ may be at least partially formed by respective slanted working surfaces 162r, 163r. Moreover, the slanted working surfaces 162r, 163r may include relief, which may facilitate movement of the excavated material away from the cutting edges 161r′, 161r″, thereby allowing the wear elements 160r′, 160r″ to effectively engage or scrape target material and/or protect a surface from wear.
As mentioned above, in an embodiment, the cutter assembly 120r may include wear elements 160r″′. The wear elements 160r′″ may be plate-shaped and/or may be approximately rectangular. In an embodiment, the wear elements 160r″′ may be positioned adjacent to the cutter element 160r″. Also, in some embodiments, wear elements 160r may comprise tungsten carbide (e.g., the wear elements 160r may include similar material to the wear elements 160b (
In some embodiments, the cutter assembly may include one or more curved or arcuate surfaces. Moreover, the superhard cutter elements may protrude to about the same height as one another from such arcuate or curved surface. As such, superhard working surfaces of the superhard cutter elements may lie along the same imaginary curved surface. For example,
In an embodiment, the support block 140s may have a curved top surface 141s. More specifically, the superhard cutter elements 150s may be secured along the curved top surface 141s in a manner that may allow at least one of the superhard cutter elements 150s to engage the target material during the operation of the TBM. In an embodiment, the curved top surface 141s may approximate a portion of an outer surface of a cylinder. Moreover, the support block 140s may include a substantially planar vertical surface 142s, which may be used to orient and/or position the cutter assembly 120s on the cutterhead of the TBM. For example, the vertical surface 142s may lie in a plane that is substantially parallel to a centerline 30s of the cutter assembly 120s.
In some embodiments, the curved top surface 141s may be oriented toward the target material when the cutter assembly 120s is mounted on the cutterhead 110 (
Also, the superhard cutter elements 150s may be distributed about the curved top surface 141s at approximately equal distances from one another. In an embodiment, a first set of the superhard cutter elements 150s may be positioned on one side of the centerline 30s, and a second set of the superhard cutter elements 150s may be positioned on the opposite side of the centerline 30s, while a single superhard cutter element 150s may be positioned between the first and second sets of the superhard cutter elements 150s.
In some embodiments, one or more of the superhard cutter elements located on the curved top surface may have a different size than one or more other superhard cutter elements located thereon. For example, superhard cutter elements 150s′ (not all labeled in
In addition, the support block 140s may have one or more slanted surfaces, such as slanted surfaces 144s, 145s, 146s, or combinations thereof. For example, the slanted surface 144s may extend from the vertical surface 142s toward the curved top surface 141s. In an embodiment, the slanted surface 144s may also be curved or arcuate in a manner that generally follows the curvature of the curved top surface 141s or other curvature. Moreover, the interface or intersection between the vertical surface 142s and the slanted surface 144s may lie along an arc. Likewise, interface or intersection between the slanted surfaces 144s and 145s also may form an arc, which may be approximately congruent with the arc formed between the vertical surface 142s and the slanted surface 144s.
Furthermore, the surface 144s may be oriented at a non-parallel angle relative to the centerline 30. In some embodiments, the surface 144s may curve or arc between the surfaces 142s and 145s. In any event, the interface between the slanted surfaces 145s and 144s may be closer to the centerline 30s than the interface between the slanted surface 144s and the vertical surface 142s.
In an embodiment, the slanted surface 145s may extend between curved top surface 141s and the slanted surface 144s. For example, the slanted surface 145s may be slanted such that the interface or intersection between the curved top surface 141s and slanted surface 145s is closer to the centerline 30s that the interface between the slanted surfaces 145s and 144s. In some examples, the slanted surface 145s may form a chamfer between the slanted surface 144s and the curved top surface 141s.
In an embodiment, the slanted surface 146s may span between the slanted surface 144s and a vertical side surface 147s. For example, the slanted surface 146s may be substantially planar or flat. Additionally or alternatively, the slanted surface 146s may be oriented at an angle relative to the vertical surface 142s. In an embodiment, the vertical surface 142s and the slanted surface 146s may form an obtuse angle with an imaginary surface that is tangent to the slanted surface 144s. The slanted surface 146s also may interface or intersect with the curved top surface 141s and slanted surface 144s. In any event, in an embodiment, the slanted surface 146s may provide a transition between the surfaces 141s, 142s, 144s, 145s, 147s, or combinations thereof.
In an embodiment, the slanted surfaces 144s, 145s, 146s, or combinations thereof may include one or more superhard cutter elements, such as superhard cutter elements 150s″ (not all labeled in
In an embodiment, at least one of the superhard cutter elements 150s″ may be positioned on the slanted surface 146s. For example, one of the superhard cutter elements 150s″ may be positioned near a junction or transition location between the surfaces 141s, 144s, and 145s and the slanted surface 146s. Also, in an embodiment, the slanted surface 145s may include superhard wear elements 150s″′ (not all labeled in
As noted above, the cutter assemblies may include any number of superhard cutter elements that may have any suitable shapes, sizes, positions, and orientations, which vary from one embodiment to the next.
In some embodiments, the cutter assembly 120t also may include superhard cutter elements 150t secured on and/or about the surface 141t. Additionally, the cutter assembly 120t may include superhard cutter elements 150t′ secured on and/or about the surface 144t. Moreover, the superhard cutter elements 150t″ may be secured on and/or about the surface 145t. Generally, the superhard cutter elements 150t, 150t′, 150t″ may engage the target material in the same or similar manner as the superhard cutter elements 150s, 150s″, 150s″′ (
Any of the superhard cutter elements 150t, 150t′, 150t″ may have a different shape and/or size than the superhard cutter elements 150s, 150s″, 150s″′ (
Also, in some embodiments, the superhard cutter elements 150t″ may be approximately semispherical or hemispherical. In any event, as noted above, the particular suitable shape and/or size of the superhard cutter elements may be selected to enhance the operation of the cutter assembly when engaging hard target material (e.g., rocks). Likewise, the support block of the cutter assembly also may include various features, as described herein, which may facilitate failing one or more particular target materials.
In an embodiment, the support block may include one or more clearance channels, which may allow failed or excavated material to move away from the superhard cutter elements, thereby extending useful life thereof (e.g., by eliminating or reducing repeated contact with or re-cutting of the failed material). For example,
Moreover, at least some of the superhard cutter elements 150u may have a non-parallel orientation relative to a vertical surface 142u of the support block 140u. Accordingly, when the cutter assembly 120u is mounted to the cutterhead of the TBM, center axes of at least some of the superhard cutter elements 150u may have a non-parallel orientation relative to the rotation axis 10 of the cutterhead 110 (
In an embodiment, the cutter assembly 120u may include clearance channels 170u, which may be positioned between at least some of the adjacent rows of the superhard cutter elements 150u. For example, the clearance channels 170u may facilitate transfer or movement of the excavated or failed material away from the superhard cutter elements 150u, which may reduce unnecessary contact of the superhard cutter elements 150u with the excavated material, thereby increasing useful life of the superhard cutter elements 150u. In some embodiments, the clearance channels 170u may extend between opposing ends of the support block 140u. For example, the clearance channels 170u may extend approximately laterally between the opposing ends of the support block 140u.
In an embodiment, the clearance channels 170u may have an approximately arcuate shape relative to the base 141u. For example, the clearance channels 170u may arc upward, such that the uppermost point of the clearance channels 170u is positioned near a centerline 30u of the cutter assembly 120u. In additional or alternative embodiments, the clearance channels may arc in any number of suitable configurations, and may have alternating or wave-like arcuate shapes. Also, in some embodiments, the clearance channels may follow a straight path, curved path, or combinations thereof.
In an embodiment, the clearance channels 170u may arc about a different center point than the arcuate paths of the rows formed by the superhard cutter elements 150u. Hence, in some embodiments, a distance from some of the superhard cutter elements 150u to the bottom of the adjacent clearance channel 170u may be different than the distance from other superhard cutter elements 150u to the bottom of the clearance channel 170u. For example, the distance to the bottom of the adjacent clearance channel 170u from the superhard cutter elements 150u closest to the centerline 30u of the support block 140u may be greater than the distance to the bottom of clearance channel 170u from the superhard cutter elements 150u farther from the centerline 30u.
In an embodiment, the clearance channels 170u may include a bottom 171u and opposing sides 172u and 173u, collectively forming, for example, an approximately U-shaped channel. In some embodiments, the bottom 171u may have a non-orthogonal orientation relative to the vertical surface 142u. For example, the bottom 171u may form an acute angle relative to the vertical surface 142u.
Also, the sides 172 and/or 173u may have non-parallel orientations relative to the vertical surface 142u. For example, the side 172u may form an acute or obtuse angle relative to the vertical surface 142u. It should be appreciated, however, that the sides 172u, 173u, or combinations thereof may have any number of suitable angles relative to one another as well as relative to surfaces of the support block 140u and to the rotation axis of the cutterhead. In any event, the clearance channels 170u may be configured in a manner that allows the excavated material to move away from the superhard cutter elements 150u along the clearance channels 170u (e.g., as new or additional excavated material enters the clearance channels 170u).
While in some embodiments the cutter assembly may include one or more arcuate and/or approximately parallel clearance channels, cutter assemblies may include any number of clearance channels that may have any suitable configuration and/or orientation relative to one another as well as relative to the support block of the cutter assembly. The embodiment illustrated in
In an embodiment, the clearance channels 170v may pass between superhard cutter elements 150v. In particular, the clearance channels 170v may pass between adjacent superhard cutter elements 150v in the same row (e.g., in a longitudinal row). For example, the clearance channels 170v may be oriented at a 45° angle relative to a base 141v of the support block 140v. Moreover, as noted above, the clearance channels 170v may form a crisscross pattern. Optionally, paths of some of the clearance channels 170v may form acute angles relative to a reference plane (e.g., relative to a portion of the base 141v), while paths of other clearance channels 170v may form obtuse angles with the same reference plane (e.g., with the same portion of the base 141v). For example, some of the clearance channels 170v may be substantially parallel to one another and/or may intersect other clearance channels 170v (e.g., the clearance channels 170v may intersect at about 90° angles).
In some embodiments, the clearance channels 170v may shave a V-shaped cross-section. For example, the clearance channels 170v may include two opposing sides 171v, 172v that may form the V-shape of the clearance channels 170v. In some embodiments, the clearance channels 170v may include a fillet or radius that extends between the opposing sides 171v, 172.
In an embodiment, the clearance channels 170v may have an arcuate configuration. That is, the clearance channels 170v may extend into the support block 140v along an arcuate path. Optionally, in some embodiments, some portions of one or more of the clearance channels 170v may be deeper (relative to one or more surfaces of the support block 140v) than other portions. For example, portions of the clearance channels 170v near a front surface 142v of the support block 140v may be shallower than portions of the clearance channels 170v near a back or mounting surface 143v of the support block 140v.
In an embodiment, portions of the clearance channels 170v located near the superhard cutter elements 150v that may have a relatively deeper engagement within the target material may be deeper than the portions of the clearance channels 170v located near the superhard cutter elements 150v that may have a relatively shallower engagement with the target material. Hence, the clearance channels 170v may provide sufficient clearance for the excavated material to move away from the superhard cutter elements 150v (e.g., based on the depth of cut of particular superhard cutter elements 150v). Moreover, such clearance channels 170v may allow the support block 140v to maintain sufficient strength and/or rigidity.
The clearance channels 170v may form pathways for the excavated material to move away from the superhard cutter elements 150v and toward exterior of the cutter assembly 120v. For example, as new or additional excavated material enters the clearance channels 170v, such material may push other material in the clearance channels 170v toward the exterior of the cutter assembly 120v. It should be appreciated, however, that the clearance channels 170v may have any number suitable orientations relative to one another as well as relative to the base 141v of the support block 140v. In any event, the excavated material may be moved away from the superhard cutter elements 150v, during use.
As mentioned above, the support block of the cutter assembly may have any suitable shape, which may vary from one embodiment to the next, and which may depend, for example, on the particular mounting location on the cutterhead of the TBM and/or on the cutting application (e.g., on the type of target material).
For example, the support block 140w may curve about a center point and may have a semi-circular shape. In an embodiment, the support block 140w may include a mounting surface (not shown) and an opposite, vertical surface 141w. In one example, the support block 140w also may include mounting holes 142w (not all labeled in
In an embodiment, the cutter assembly 120w may include a slanted surface 143w, which may be oriented at a non-parallel angle relative to the mounting surface and/or to the vertical surface 141w. For example, the slanted surface 143w may be at approximately 45° angle to the surface 141w. In an embodiment, after mounting the cutter assembly 120w to the cutterhead, the surface 143w may be oriented at 45° angle to the front surface 111 of the cutterhead 110 (
As described above, the superhard cutter elements 150w may be secured to the support block 140w. In one example, the superhard cutter elements 150w may be secured on and/or about the surface 143w. For example, the superhard cutter elements 150w may form a row along the slanted surface 143w. Moreover, in an embodiment, the slanted surface 143w may be curved (e.g., in a manner that follows a semi-circle, which may be centered at the same center point as the shape of the support block 140w). Additionally, center axes of at least some of the superhard cutter elements 150w may be oriented approximately perpendicular relative to the slanted surface 143w (e.g., if the superhard working surfaces 151w are planar, they may be approximately parallel or flush relative to the slanted surface 143w).
In an embodiment, the superhard cutter elements 150w may have approximately planar superhard working surfaces 151w. For example, one or more cutting edges may define or encompass the planar superhard working surfaces 151w about perimeters thereof. The cutting edges and/or the superhard working surfaces 151w may engage and fail the target material.
Also, in some embodiments, the cutter assembly 120w may include a wear element 160w that may include the slanted surface 143w. Moreover, in an embodiment, the superhard cutter elements 150w may be attached or bonded to the wear element 160w. For example, the wear element 160w may include cemented tungsten carbide or similar material. The wear element 160w may be permanently or removably secured to the support block 140w in any suitable manner, such as by brazing, fastening, press-fitting, etc.
In an embodiment, the wear element 160w may include a cutting edge 161w, which may engage and/or fail the target material. For example, the superhard working surfaces 151w may be positioned higher or above the cutting edge 161w, such that the superhard cutter elements 150w engage the target material before engagement thereof by the cutting edge 161w. Accordingly, in some embodiments, the superhard cutter elements 150w may at least partially fail the target material, and the cutting edges 161w may scrape and remove the failed material that may still be attached to the bulk of the target material.
In some embodiments, the cutter assembly 120w may be mounted on the cutterhead in a manner that rotation of the cutterhead produces movement of the superhard cutter elements 150w in a manner that the superhard working surfaces 151w of the superhard cutter elements 150w engage and fail the target material. For example, the vertical surface 142w may be oriented approximately orthogonally relative to the direction of the rotation of the cutterhead. As such, in an embodiment, the superhard cutter elements 150w may engage the target material at approximately the same angle as the angle of the slanted surface 143w.
While the cutter assembly 120w described above includes approximately planar superhard cutter elements 150w, it should be appreciated that similar cutter assemblies may include superhard cutter elements of any suitable shapes and/or sizes. For example,
In an embodiment, the superhard cutter elements 150x may be designed to engage a different target material (as compared with the superhard cutter elements 150w (
In some embodiments, the cutter assembly may include multiple or multi-level working or cutting areas.
For example, the cutter assembly 120y may include side cutting areas 121y, 121y′, 121y″, or combinations thereof. In additional or alternative embodiments, the cutter assembly 120y also may include top cutting areas 122y, 122y′, 122y″, 122y″′, or combinations thereof. In some embodiments, the cutter assembly 120y may be approximately symmetric about a centerline 30y. Hence, the cutter assembly 120y may have symmetric cutting areas (i.e., any of the cutting areas 121y, 121y′, 121y″, 122y, 122y′, 122y″, 122y″′) located on both sides of the centerline 30y. Moreover, the cutting areas 121y, 121y′, 121y″, 122y, 122y′, 122y″, 122y″′ may form or define multiple levels of the cutter assembly 120y, as shown in
In some embodiments, one, some, or all of the top cutting areas 122y, 122y′, 122y″, 122y″′ may be approximately parallel to a base 141y of the support block 140y. In other words, when the cutter assembly 120y is mounted on the cutterhead of the TBM, one, some, or all of the top cutting areas 122y, 122y′, 122y″, 122y″′ may be approximately perpendicular to the rotation axis of the cutterhead. Alternatively, however, any of the top cutting areas 122y, 122y′, 122y″, 122y″′ may form non-parallel angles with the base 141y and/or with the surface of the cutterhead.
In some embodiments, one, some, or all of the top cutting areas 122y, 122y′, 122y″, 122y″′ may have an approximately planar of flat profile. As noted above, the top cutting areas 122y, 122y′, 122y″, 122y″ may include superhard cutter elements 150y. Specifically, center axes of the superhard cutter elements 150y may be oriented approximately parallel relative to the centerline 30y or to one another.
Also, in an embodiment, one, some, or all of the top cutting areas 122y, 122y′, 122y″, 122y′″ may be at least partially arcuate. For example, the top cutting area 122y may arc about a center point. Accordingly, the superhard cutter elements 150y of the top cutting area 122y may gradually engage the target material, as the cutterhead rotates. It should be appreciated that center axes of one, some, or all of the superhard cutter elements 150y of the top cutting area 122y may be oriented at non-parallel angles relative to the centerline 30y, as the superhard cutter elements 150y form arcuate rows or arrangements that may define the arcuate shape of the top cutting area 122y.
Also, multiple levels formed by the top cutting areas 122y, 122y′, 122y″, 122y′″ may facilitate multi-level engagement and/or cutting or failing of the target material. Thus, the cutter assembly 120y may fail the target material in steps or stair patterns, which may reduce load on any single cutting area (e.g., by having other or additional cutting areas fail and/or remove at least some of the target material).
In an embodiment, the side cutting areas 121y, 121y′, 121y″ also may engage and/or fail the target material. Additionally or alternatively, the side cutting areas 121y, 121y′, 121y″ may protect one, some, or all of the top cutting areas 122y, 122y′, 122y″, 122y′″ as well as the superhard cutter elements 150y thereof. In any event, in some embodiments, the side cutting areas 121y, 121y′, 121y″ may be substantially planar.
In some embodiments, the plane of the cutting areas 121y, 121y′, 121y″ may have a non-parallel orientation relative to the centerline 30y. For example, one, some or all of the side cutting areas 121y, 121y′, 121y″ may form acute angles with one, some, or all of the corresponding top cutting areas 122y′, 122y″, 122y′″ (which may be perpendicular to the centerline 30y). Hence, one, some or all of the side cutting areas 121y, 121y′, 121y″ may define or form an angle relative to one, some, or all of the corresponding top cutting areas 122y, 122y′, 122y″, 122y′″ that are positioned above the side cutting areas 121y, 121y′, 121y″. The angle may facilitate movement of the failed and/or removed target material away from the top cutting areas 122y, 122y′, 122y″, 122y′″. It should be appreciated, however, that the side cutting areas 121y, 121y′, 121y″ may be oriented at any suitable angle (e.g., relative to the centerline 30y and/or relative to the top cutting areas 122y, 122y′, 122y″, 122y″), which may vary from one embodiment to the next.
In some embodiments, the superhard cutter elements 150y′ and 150y″ may be different from each other. For example, the superhard cutter elements 150y″ may be bigger than the superhard cutter elements 150y′. It should be appreciated that any of the cutting areas 121y, 121y′, 121y″, 122y, 122y′, 122y″, 122y′″ may include any of the superhard cutter elements 150y′, 150y″ or combinations thereof. In one example, the cutting areas 121y, 121y′, 121y″, 122y, 122y′, 122y″ may include the superhard cutter elements 150y′, while the cutting area 122y′″ may include the superhard cutter elements 150y″.
As mentioned above, any of the cutter assemblies may include any of the superhard cutter elements described herein.
The superhard cutter element 150′ may include a substrate 152′ and a superhard table 153′, which may be bonded or otherwise secured to the substrate 152′. Specifically, the superhard table 153′may be bonded to the substrate 152′ along a planar interface 154′. Alternatively, however, the interface between the superhard table 153′ and the substrate may be non-planar.
The superhard table 153′ may include the superhard working surface 151′. Furthermore, in some embodiments, the superhard table 153′ may have a chamfer 155′ extending between the superhard working surface 151′ and the peripheral surface of the superhard table 153′; at least a portion of the chamfer 155′ also may form or define one or more cutting edges of the superhard cutter element 150′. Additionally or alternatively, the superhard cutter element may include a substantially sharp edge between the superhard working surface and the peripheral surface.
In some embodiments, the superhard working surface 151′ and the peripheral surface of the superhard cutter element 150′, may form a right cylinder (e.g., the right cylinder may be centered on a center axis 50′ of the cutter element 150′). As mentioned above, superhard cutter element 150′ may be secured to a support block by positioning the superhard cutter element 150′ at least partially within a recess in the support block. Consequently, the superhard working surface 151′ may be oriented approximately orthogonally relative to the surface (or center axis thereof) that defines the recess in the support block. As such, the orientation of the superhard working surface 151′ relative to the support block may be controlled or determined by the orientation of the recess relative to the support block.
In an embodiment, the superhard table 153′ may comprise polycrystalline diamond and the substrate 152′ may comprise cobalt-cemented tungsten carbide. Furthermore, in any of the embodiments disclosed herein, the polycrystalline diamond table may be leached to at least partially remove or substantially completely remove a metal-solvent catalyst (e.g., cobalt, iron, nickel, or alloys thereof) that was used to initially sinter precursor diamond particles to form the polycrystalline diamond. In another embodiment, an infiltrant used to re-infiltrate a preformed leached polycrystalline diamond table may be leached or otherwise have a metallic infiltrant removed to a selected depth from a superhard working surface. Moreover, in any of the embodiments disclosed herein, the polycrystalline diamond may be un-leached and include a metal-solvent catalyst (e.g., cobalt, iron, nickel, or alloys thereof) that was used to initially sinter the precursor diamond particles that form the polycrystalline diamond and/or an infiltrant used to re-infiltrate a preformed leached polycrystalline diamond table. Examples of methods for fabricating the superhard tables and superhard materials and/or structures from which the superhard tables and elements may be made are disclosed in U.S. Pat. Nos. 7,866,418; 7,998,573; 8,034,136; and 8,236,074; the disclosure of each of the foregoing patents is incorporated herein, in its entirety, by this reference.
The diamond particles that may be used to fabricate the superhard table 153′ in a high-pressure/high-temperature process (“HPHT)” may exhibit a larger size and at least one relatively smaller size. As used herein, the phrases “relatively larger” and “relatively smaller” refer to particle sizes (by any suitable method) that differ by at least a factor of two (e.g., 30 μm and 15 μm). According to various embodiments, the diamond particles may include a portion exhibiting a relatively larger size (e.g., 70 μm, 60 μm, 50 μm, 40 μm, 30 μm, 20 μm, 15 μm, 12 μm, 10 μm, 8 μm) and another portion exhibiting at least one relatively smaller size (e.g., 15 μm, 12 μm, 10 μm, 8 μm, 6 μm, 5 μm, 4 μm, 3 μm, 2 μm, 1 μm, 0.5 μm, less than 0.5 μm, 0.1 μm, less than 0.1 μm). In an embodiment, the diamond particles may include a portion exhibiting a relatively larger size between about 10 μm and about 40 μm and another portion exhibiting a relatively smaller size between about 1 μm and 4 μm. In another embodiment, the diamond particles may include a portion exhibiting the relatively larger size between about 15 μm and about 50 μm and another portion exhibiting the relatively smaller size between about 5 μm and about 15 μm. In another embodiment, the relatively larger size diamond particles may have a ratio to the relatively smaller size diamond particles of at least 1.5. In some embodiments, the diamond particles may comprise three or more different sizes (e.g., one relatively larger size and two or more relatively smaller sizes), without limitation. The resulting polycrystalline diamond formed from HPHT sintering the aforementioned diamond particles may also exhibit the same or similar diamond grain size distributions and/or sizes as the aforementioned diamond particle distributions and particle sizes. Additionally, in any of the embodiments disclosed herein, the superhard elements may be free-standing (e.g., substrateless) and/or formed from a polycrystalline diamond body that is at least partially or fully leached to remove a metal-solvent catalyst initially used to sinter the polycrystalline diamond body.
As noted above, the superhard table 153′ may be bonded to the substrate 152′. For example, the superhard table 153′ comprising polycrystalline diamond may be at least partially leached and bonded to the substrate 152′ with an infiltrant exhibiting a selected viscosity, as described in U.S. patent application Ser. No. 13/275,372, entitled “Polycrystalline Diamond Compacts, Related Products, And Methods Of Manufacture,” the entire disclosure of which are incorporated herein by this reference. In an embodiment, at least partially leached polycrystalline diamond table may be fabricated by subjecting a plurality of diamond particles (e.g., diamond particles having an average particle size between 0.5 μm to about 150 μm) to an HPHT sintering process in the presence of a catalyst, such as cobalt, nickel, iron, or an alloy of any of the preceding metals to facilitate intergrowth between the diamond particles and form a polycrystalline diamond table comprising bonded diamond grains defining interstitial regions having the catalyst disposed within at least a portion of the interstitial regions. The as-sintered polycrystalline diamond table may be leached by immersion in an acid or subjected to another suitable process to remove at least a portion of the catalyst from the interstitial regions of the polycrystalline diamond table, as described above. The at least partially leached polycrystalline diamond table includes a plurality of interstitial regions that were previously occupied by a catalyst and form a network of at least partially interconnected pores. In an embodiment, the sintered diamond grains of the at least partially leached polycrystalline diamond table may exhibit an average grain size of about 20 μm or less. Subsequent to leaching the polycrystalline diamond table, the at least partially leached polycrystalline diamond table may be bonded to a substrate in an HPHT process via an infiltrant with a selected viscosity. For example, an infiltrant may be selected that exhibits a viscosity that is less than a viscosity typically exhibited by a cobalt cementing constituent of typical cobalt-cemented tungsten carbide substrates (e.g., 8% cobalt-cemented tungsten carbide to 13% cobalt-cemented tungsten carbide).
Additionally or alternatively, the superhard table 153′ may be a polycrystalline diamond table that has a thermally-stable region, having at least one low-carbon-solubility material disposed interstitially between bonded diamond grains thereof, as further described in U.S. patent application Ser. No. 13/027,954, entitled “Polycrystalline Diamond Compact Including A Polycrystalline Diamond Table With A Thermally-Stable Region Having At Least One Low-Carbon-Solubility Material And Applications Therefor,” the entire disclosure of which are incorporated herein by this reference. The low-carbon-solubility material may exhibit a melting temperature of about 1300° C. or less and a bulk modulus at 20° C. of less than about 150 GPa. The low-carbon-solubility, in combination with the high diamond-to-diamond bond density of the diamond grains, may enable the low-carbon-solubility material to be extruded between the diamond grains and out of the polycrystalline diamond table before causing the polycrystalline diamond table to fail during operations due to interstitial-stress-related fracture.
In some embodiments, the polycrystalline diamond, which may form the superhard table 153′, may include bonded-together diamond grains having aluminum carbide disposed interstitially between the bonded-together diamond grains, as further described in U.S. patent application Ser. No. 13/100,388, entitled “Polycrystalline Diamond Compact Including A Polycrystalline Diamond Table Containing Aluminum Carbide Therein And Applications Therefor,” the entire disclosure of which are incorporated herein by this reference.
While in some embodiments the superhard cutter element may include a working surface that is approximately orthogonal to the peripheral surface thereof, the present disclosure is not so limited. Particularly,
The superhard working surface 151″ may have any suitable orientation relative to the peripheral surface of the superhard cutter elements 150″ and/or centerline about which the peripheral surface spans. For example, the peripheral surface of the superhard cutter elements 150″ may span about a center axis 50″. Hence, in an embodiment, the superhard working surface 151″ may be oriented at an acute slant angle 41″ relative to the center axis 50″. As noted above, however, the superhard working surface 151″ may have any suitable orientation and slant angle. Furthermore, in some embodiments, the superhard cutter elements may have non-planar superhard working surfaces and/or may have non-planar interfaces between the substrate and the superhard table 153″.
For example,
In an embodiment, the superhard working surface 151″′ may have a domed, hemispherical or semispherical shape that, in some examples, may be centered about a center axis 50″′. Similarly, the interface 154″′ between the superhard table 153″′ and the substrate 152″′ may be at least partially domed, hemispherical or semispherical. For example, the semispherical portion of the interface 154″′ and the superhard working surface 151″′ may be centered about the same or similar center point. As such, at least a portion of the superhard table 153″′ may have an approximately uniform thickness.
Moreover, in some embodiments, the interface 154″′ may include non-spherical portions (e.g., planar, irregular, etc.). Similarly, the superhard working surface 151″′ may include other non-planar shapes. It should be also appreciated that any of the superhard cutter elements may include multiple superhard working surfaces, which may be included in or formed by the superhard tables. In other words, one or more of the superhard working surfaces of the superhard cutter elements may vary from one embodiment to the next and may be shaped, sized, or otherwise configured to facilitated cutting, scraping, or otherwise failing the target material, when the superhard cutter element is included in an operating cutter assembly.
In at least one embodiment, as shown in
For example, the superhard cutter element 150″″ may include a superhard table 153″″ bonded to a substrate 152″″. In an embodiment, the substrate 152″″ may be generally cylindrical and/or may be centered about a center axis 50″″. Also, in at least one embodiment, at least a portion of the superhard table 153″″ may have an approximately uniform thickness (e.g., an interface 154″″ between the superhard table 153″″ and the substrate 152″″ may approximately follow the working surface 151″″).
While various aspects and embodiments have been disclosed herein, other aspects and embodiments are contemplated. The various aspects and embodiments disclosed herein are for purposes of illustration and are not intended to be limiting. Additionally, the words “including,” “having,” and variants thereof (e.g., “includes” and “has”) as used herein, including the claims, are open ended and shall have the same meaning as the word “comprising” and variants thereof (e.g., “comprise” and “comprises”).
Claims
1. A cutter assembly for mounting on a cutterhead of a tunnel boring machine (“TBM”) and engaging a target material, the cutter assembly comprising:
- a support block sized and configured to be attached to the cutterhead of the TBM, the support block including a leading surface, a back surface, and a top surface extending between the leading surface and the back surface; and
- a plurality of polycrystalline diamond cutter elements secured to the support block, each of the plurality of polycrystalline diamond cutter elements including a polycrystalline diamond working surface, the plurality of polycrystalline diamond cutter elements including: one or more first polycrystalline diamond cutter elements having a substantially nonplanar polycrystalline diamond working surface, the one or more first polycrystalline diamond cutter elements extend outward from the top surface of the support block; and one or more second polycrystalline diamond cutter elements having a substantially planar polycrystalline diamond working surface, wherein a center axis of the one or more second polycrystalline diamond cutter elements is oriented at an acute angle relative to a centerline of the support block.
2. The cutter assembly of claim 1, further comprising one or more wear elements secured to the top surface of the support block.
3. A cutter assembly for mounting on a cutterhead of a tunnel boring machine (“TBM”) and engaging a target material, the cutter assembly comprising:
- a support block sized and configured to be attached to the cutterhead of the TBM, the support block including a curved top surface, a planar vertical surface, and a first slanted surface extending at least partially between the curved top surface and the planar vertical surface; and
- a plurality of polycrystalline diamond cutter elements secured to the support block, the plurality of polycrystalline diamond cutter elements including: a first portion of polycrystalline diamond cutter elements each having a center axis that is oriented at an acute angle relative to a centerline of the support block and a polycrystalline diamond working surface that is one of a domed polycrystalline diamond working surface or a substantially planar polycrystalline diamond working surface; and a second portion of polycrystalline diamond cutter elements each extending outward from the curved top surface of the support block.
4. The cutter assembly of claim 3, wherein each polycrystalline diamond cutter element of the second portion of the plurality of polycrystalline diamond cutter elements includes a substantially nonplanar polycrystalline diamond working surface.
5. The cutter assembly of claim 3, further comprising a second slanted surface extending between at least a portion of the curved top surface and the first slanted surface, wherein the plurality of polycrystalline diamond cutter elements includes a third portion of the polycrystalline diamond cutter elements extending outward from the second slanted surface.
6. The cutter assembly of claim 5, wherein each polycrystalline diamond cutter element of the third portion of the polycrystalline diamond cutter elements has a nonplanar polycrystalline diamond working surface.
7. The cutter assembly of claim 3, wherein each polycrystalline diamond cutter element of the first portion of the plurality polycrystalline diamond cutter elements has a substantially planar polycrystalline diamond working surface.
8. A cutter assembly for mounting on a cutterhead of a tunnel boring machine (“TBM”) and engaging a target material, the cutter assembly comprising:
- a support block sized and configured to be attached to the cutterhead of the TBM, the support block including a first surface, a second surface, and a third surface, the second surface being slanted between the first surface and the third surface; and a plurality of polycrystalline diamond cutter elements, each of the plurality of polycrystalline diamond cutter elements including a substrate secured to the support block and a superhard table secured to the substrate distal to the support block, wherein: the superhard table of each polycrystalline diamond cutter element of a first portion of the plurality of polycrystalline diamond cutter elements includes a substantially nonplanar polycrystalline diamond working surface; the superhard table of each polycrystalline diamond cutter element of a second portion of the plurality of polycrystalline diamond cutter elements includes a substantially planar polycrystalline diamond working surface; one or more first polycrystalline diamond cutter elements of the plurality of polycrystalline diamond cutter elements extend from at least one of the first surface or the second surface; and one or more second polycrystalline diamond cutter elements of the plurality of polycrystalline diamond cutter elements extend at least partially from the third surface and include a center axis oriented at an acute angle relative to a centerline of the support block.
9. The cutter assembly of claim 8, wherein:
- the first surface includes a back surface;
- the second surface includes a top surface;
- the third surface includes a leading surface;
- the one or more second polycrystalline diamond cutter elements extend at least partially from both the top surface and the leading surface.
10. The cutter assembly of claim 9, wherein each of the one or more second polycrystalline diamond cutter elements includes the substantially planar polycrystalline diamond working surface.
11. The cutter assembly of claim 10, wherein each of the first polycrystalline diamond cutter elements extends from the back surface of the support block and includes the substantially nonplanar polycrystalline diamond working surface.
12. The cutter assembly of claim 11, further comprising one or more wear elements secured to the top surface of the support block.
13. The cutter assembly of claim 10, wherein each of the first polycrystalline diamond cutter elements extends from the top surface of the support block and includes the substantially nonplanar polycrystalline diamond working surface.
14. The cutter assembly of claim 8, wherein:
- the first surface includes a curved top surface;
- the second surface includes first slanted surface;
- the third surface includes a second slanted surface, the first slanted surface being slanted between the second slanted surface and the curved top surface;
- each of the one or more first polycrystalline diamond cutter elements of the plurality of polycrystalline diamond cutter elements extends from the curved top surface and includes the substantially nonplanar polycrystalline diamond working surface; and
- each of the one or more second polycrystalline diamond cutter elements of the plurality of polycrystalline diamond cutter elements extends from the second slanted surface and includes the substantially planar polycrystalline diamond working surface.
15. The cutter assembly of claim 14, wherein the plurality of polycrystalline diamond cutter elements includes one or more third polycrystalline diamond cutter elements extending outward from the first slanted surface.
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Type: Grant
Filed: Jun 26, 2018
Date of Patent: Jul 2, 2019
Patent Publication Number: 20180298755
Assignee: APERGY BMCS ACQUISITION CORPORATION (Orem, UT)
Inventors: Edwin Sean Cox (Spanish Fork, UT), Regan Leland Burton (Saratoga Springs, UT)
Primary Examiner: David J Bagnell
Assistant Examiner: Michael A Goodwin
Application Number: 16/018,645
International Classification: E21D 9/11 (20060101); E21C 35/183 (20060101); E21D 9/10 (20060101); E21C 35/18 (20060101);